Robust grant-free transmissions

ABSTRACT

Various arrangements for performing uplink grant-free transmissions are presented herein. An instance of user equipment (UE) may determine data that is to be transmitted using a grant-free (GF) uplink transmission to a base station of a cellular network. The UE may select a first GF resource block and a second GF resource block. The UE may transmit a GF transmission that comprises a data payload and a first pointer at the first GF resource block. The first pointer may refer to the second GF resource block.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent ApplicationNo. 62/754,075, filed on Nov. 1, 2018, entitled “Robust Grant-FreeTransmissions,” the disclosure of which is hereby incorporated byreference in its entirety for all purposes.

BACKGROUND

Grant-free (GF) transmissions allow for user equipment (UE) to transmitdata packets at defined times on defined frequencies (e.g., sub-carriersof OFDM physical resource blocks) without first requesting and receivinga reservation with a base station. Such grant-free transmissionsdecrease the amount of communication delay and overhead required toschedule a data transmission from the UE to a base station. However,since the frequency and time slot is not reserved for the UE, it ispossible that a second UE will transmit data on the same frequency andduring the same time slot. When two UEs transmit at the same time on thesame frequency, a collision results, which may typically prevent thebase station from successfully receiving data transmitted by either UEas part of the collision.

SUMMARY

Various arrangements for performing uplink grant-free transmissions arepresented herein. An instance of user equipment may determine that datathat is to be transmitted using a grant-free uplink transmission to abase station of a cellular network. A first grant-free resource blockmay be selected. A plurality of grant-free resource blocks can define aplurality of sets of subcarrier frequencies, a plurality of timeslots,or both for data to be transmitted to the base station of the cellularnetwork without a reservation. selecting, by the instance of userequipment, a second grant-free resource block. A grant-free transmissionmay be transmitted by the UE instance that includes a data payload and afirst pointer at the first grant-free resource block. The first pointercan refer to the second grant-free resource block.

Embodiments of such an arrangement can include one or more of thefollowing features: The first grant-free resource block and the secondgrant-free resource block can occur during a same timeslot on differentfrequencies. The first grant-free resource block and the secondgrant-free resource block can occur during different timeslots on a sameset of frequencies. The first grant-free resource block and the secondgrant-free resource block can occur during different timeslots ondifferent frequencies. The instance of user equipment can transmit asecond grant-free transmission that comprises the data payload and asecond pointer at the second grant-free resource block. The base stationmay receive the grant-free transmission transmitted by the instance ofuser equipment on the first grant-free resource block. A collision maybe detected by the base station on the second grant-free resource block.The collision can result from the second grant-free transmission beingreceived during a same timeslot and a same frequency as a thirdgrant-free transmission from a second instance of user equipment. Basedon the first pointer of the grant-free transmission, interferencecancellation may be performed to subtract at least a portion of thegrant-free transmission from the received collision to reconstruct thethird grant-free transmission transmitted by the second instance of userequipment at the second grant-free resource block. The base station canbe part of a 5G cellular network. Selecting the first grant-freeresource block and selecting the second grant-free resource block may beperformed randomly by the instance of user equipment. The grant-freetransmission may include a second pointer to a third grant-free resourceblock. The third grant-free resource block may have occurred earlier intime than the grant-free resource block and the second grant-freeresource block may occur later in time than the grant-free resourceblock.

BRIEF DESCRIPTION OF THE DRAWINGS

A further understanding of the nature and advantages of variousembodiments may be realized by reference to the following figures. Inthe appended figures, similar components or features may have the samereference label. Further, various components of the same type may bedistinguished by following the reference label by a dash and a secondlabel that distinguishes among the similar components. If only the firstreference label is used in the specification, the description isapplicable to any one of the similar components having the same firstreference label irrespective of the second reference label.

FIG. 1 illustrates an example of a cellular system in which multipleinstances of user equipment are communicating with a base station.

FIG. 2 illustrates grant-free resource blocks that may be available forthe transmission of data to multiple instances of user equipment.

FIG. 3A illustrates an embodiment of a grant-free resource blocks inwhich multiple instances of user equipment are transmitting data.

FIG. 3B illustrates an embodiment of a grant-free resource blocks inwhich multiple instances of user equipment have transmitting data and acollision has resulted.

FIG. 4A illustrates an embodiment of a one-way frequency-domainlinked-list data structure.

FIG. 4B illustrates an embodiment of a two-way frequency-domainlinked-list data structure.

FIG. 5 illustrates an embodiment of a collision involving a two-wayfrequency-domain linked-list data structure.

FIG. 6A illustrates an embodiment of a one-way time-domain linked-listdata structure.

FIG. 6B illustrates an embodiment of a two-way time-domain linked-listdata structure.

FIG. 6C illustrates an embodiment of a time-domain linked pseudorandomcode linked data structure.

FIG. 7 illustrates an embodiment of a consecutive index time-domain datastructure.

FIG. 8 illustrates an embodiment of a method for using a linked-listdata structure to correct for grant-free transmission collisions.

DETAILED DESCRIPTION

Instances of UE are permitted to send GF transmission on allocatedresource blocks. A resource block can refer to a timeslot and a numberof subcarriers in the frequency domain, such as 12 subcarriers. In thetime domain, such as for 5G, the time slot may be for 14 OFDM symbols.Resource blocks may also be applied to mini-slot transmissions insteadof slot transmissions. (For the purposes of this document, “time slot”can be understood as including mini-slots.) The instance of UE cantransmit the GF transmission without getting permission from the basestation to transmit on a resource block allocated for GF transmissions.However, other instances of UE may also transmit on the same resourceblock. If two or more instances of UE transmit on the same resourceblock, a collision may occur, preventing the base station from properlyreceiving the two or more transmissions from the two or more instancesof UE. In embodiments detailed herein, rather than transmitting a datapayload using a single resource block, an instance of UE may beconfigured to transmit the same data payload on multiple resource blocksalong with one or more points that refer to one or more of the otherresource blocks on which the payload was transmitted. Such anarrangement not only can increase the likelihood that at least one ofthe transmissions will be successfully received by the base station, butalso if the base station has a copy of the data that was received aspart of the collision, the data involved in the collision can beprocessed and reconstructed to decipher the received data involved inthe collision. As detailed herein, various arrangements for usingpointers and indexes in relation to GF transmissions are disclosed.

FIG. 1 illustrates an embodiment of a system 100 in which multipleinstances of UE are communicating with a base station of a cellularnetwork. In system 100, UE 110 is present. Instances of user equipmentmay be forms of wireless electronic devices that can communicate with acellular network, such as a 5G cellular network. Other forms of cellularnetworks are possible (e.g., 3G, 4G, or a later generation of cellularnetwork). Wireless electronic devices may be cellphones, smartphones,computers, gaming devices, smart-home devices, smart sensors, etc.

Instances of UE 110 may have various components on-board. For instance,each instance of UE may have hardware, software, and/or firmware thatpermits communication with one or more types of wireless networks, suchas 5G NR cellular networks. Additionally, UE 110 may have othercomponents. For simplicity, several of such components are shown foronly UE 110-3. For UE 110-3, UE configuration data 111 is stored using anon-transitory processor-readable medium, such as memory. UEconfiguration data 111 may be received from base station 120 and maydictate which resource blocks are reserved for GF transmissions and howsuch GF transmissions should be transmitted. UE configuration data 111may define the number of times that a particular payload of data shouldbe sent on different resource blocks. Further, UE configuration data 111may define whether frequency and/or time should be randomized or if aconsecutive group of transmissions (in either the frequency or timedomain) are to be sent having the same payload. GF transmissionrandomizer 112, which can be implemented using a multi-purpose processoror a dedicated component, may be used to randomly select a resourceblock. By different instances of UE performing a randomized selection ofresource blocks, the likelihood of collisions may be reduced.

Multiple instances of UE 110 may communicate with base station 120. Basestation 120 may provide access to network 130 (which may be a privatenetwork (e.g., a cellular service provider's network, or a publicnetwork, such as the Internet) for UE that are currently communicatingwith base station 120. Base station 120 may be part of a cellularnetwork, such as a 5G cellular network. Therefore, base station 120 maybe a gNodeB. Base station 120 may have various hardware components foundin a gNodeB. Base station 120 may have UE configuration data 121 storedusing a non-transitory processor-readable medium. UE configuration data121 may be transmitted to instances of UE 110 when UE 110 communicatewith base station 120. Base station 120 may also have interferencecancellation engine 122. Interference cancellation engine 122 may beable to resolve data involved in a collision if interferencecancellation engine 122 has access to a copy of one of the instances ofthe transmitted messages involved in the collision (such as byperforming successive interference cancellation).

Services in addition to network access may be provided, such as datareporting, telephone calls, text messaging, etc. Such services may relyon at least some packetized data being transmitted from the UE to thebase station.

The wireless network of which base station 120 is a member, may supportgrant-free (GF) transmissions. For example, the 3GPP NR (New Radio)specification (also referred to as 5G) allows for GF uplinktransmissions from UE to a base station. A GF transmission refers to atransmission that has not been previously scheduled from the UE to thebase station. Rather, particular resource blocks, are reserved for grantfree transmissions. A resource block refers to a defined time periodoccurring at a defined time (a time slot or mini-slot), on a definedfrequency (a subcarrier group, such as of 12 subcarriers). Any UE may bepermitted to transmit a GF transmission on such a resource block withoutfirst requesting and obtaining a reservation from base station 120.

Such an arrangement can decrease the amount of overhead and delayassociated with scheduling a transmission between an instance of UE 110and base station 120. However, since instances of UE 110 are not awareof if or when other instances of UE 110 are transmitting GFtransmissions, collisions between transmissions are possible. Acollision results when multiple instance of UE (e.g., UE 110-1 and110-2) each transmit a GF transmission on a same resource block. Such acollision can result in base station 120 being unable to successfullydecode or interpret the GF transmission from either instance of UE dueto interference from the GF transmission from the other UE.

FIG. 2 illustrates an embodiment 200 of grant-free resource blocks thatmay be available for the transmission of data from multiple instances ofuser equipment to a base station. In embodiment 200, the y-axisrepresents different sub-carrier frequencies in the frequency domain andthe x-axis represents different pre-defined time slots (or in 5G orother networks that support the technology, mini-slots). In FIG. 2, theshaded resource blocks, such as resource block 202, are examples ofresource blocks during which instances of UE in communication with abase station are permitted to transmit grant-free transmissions. In FIG.2, the blank resource blocks, such as resource block 201, are examplesof resource blocks that are reserved for purposes other than grant-freetransmissions. It should be understood that the illustrated number ofgrant-free resources, the number of time slots, and the number ofresource blocks are for example purposes only.

FIG. 3A illustrates an embodiment 300A of resource blocks for grant-freetransmissions in which multiple instances of user equipment havetransmitted data. The specific resource block in which a UE sends a GFtransmission may be randomly selected by the UE. Such random selectionmay help eliminate collisions between data transmitted by different UEs.Embodiment 300A represents when and on what sub-carrier frequencies isreceived by a base station. No UE transmitted a GF transmission inresource block 301; a first UE (e.g., UE 110-1) transmitted a GFtransmission at resource block 302; and a second UE (e.g., UE 110-2)transmitted a GF transmission at resource block 303. Since the GFtransmissions were transmitted on different resource blocks, there is nocollision and the base station can be expected to receive both GFtransmissions successfully.

In contrast, FIG. 3B illustrates an embodiment 300B of resource blocksfor grant-free transmissions in which multiple instances of UE havetransmitted data and a collision has resulted. In embodiment 300B, twoUEs transmitted a GF transmission on resource block 310. Therefore, thebase station receives both GF transmissions in the same time slot on thesame set of sub-carrier frequencies. Data transmitted by each UE may bereceived but may be indecipherable by the base station withoutadditional information. Therefore, unless additional information isprovided, the GF transmission by each UE at resource block 310 may belost.

Rather than transmitting a GF transmission once, a UE may perform “K”repetitions by sending the same GF transmission multiple times (“K”times). Some or all of these replicated GF transmissions may be linkedto another GF transmission that includes the same data payload and useone or more pointers. Such replication may be performed in the frequencydomain, the time domain, or both.

FIG. 4A illustrates an embodiment of a one-way frequency-domainlinked-list data structure 400A. Data structure 400A represents multipleresource blocks in which GF transmissions are permitted. Each of theresource blocks in data structure 400A occur in a same timeslot, but ondifferent sub-carrier frequencies. The UE transmits GF transmissionsthat have the same payload on resource blocks 401, 402, and 403. Each ofthese GF transmissions include a pointer value that refers to anotherresource block on which the same data payload was transmitted (the datapayload is said to be “replicated”). The GF transmission transmitted bythe UE at resource block 401 includes a pointer value (which isrepresented by arrow 411) that refers to resource block 402. The GFtransmission transmitted by the UE at resource block 402 includes apointer value (which is represented by arrow 412) that refers toresource block 403. The GF transmission transmitted by the UE atresource block 403 includes a pointer value (which is represented byarrow 413) that refers to resource block 403. By the GF transmission ofresource block 403 referring to itself, this is an indication that theGF transmission of resource block 403 is a last GF transmission of theseries of linked GF transmissions.

The specific number (“K”) of repetitions GF transmissions sent by a UEmay be based on a predefined value. For instance, a network or basestation may have instructed the UE a number of times that a GFtransmission should be replicated can be stored in the configurationdata of the UE. The number of times a transmission is replicated may bevaried based on the amount of GF transmissions being sent collectivelyby UE to a base station. The greater the number GF transmissions beingsent by different instances of UE, the more replications that may beneeded by each UE to increase the likelihood of a successful receptionby the base station without a collision.

FIG. 4B illustrates an embodiment of a two-way frequency-domainlinked-list data structure 400B. Data structure 400B represents multipleresource blocks in which GF transmissions are permitted. Each of theresource blocks in data structure 400A occur in a same timeslot, but ondifferent set of sub-carrier frequencies. The UE transmits GFtransmissions that have the same payload on resource blocks 421 and 422.Each of these GF transmissions includes two pointer values that refer toother resource blocks on which the same data payload was transmitted.The GF transmission transmitted by the UE at resource block 421 includesa first pointer value (which is represented by arrow 430) that refers toresource block 422. The GF transmission transmitted by the UE atresource block 421 also includes a second pointer value (which isrepresented by arrow 433) that refers back to resource block 421,indicating that no further resource block at a lower set of sub-carrierfrequencies contains the replicated payload. The GF transmissiontransmitted by the UE at resource block 422 includes a first pointervalue (which is represented by arrow 431) that refers to resource block422, indicating that no further resource block at a higher set ofsub-carrier frequencies in frequency domain contains the replicatedpayload. The GF transmission transmitted by the UE at resource block 422also includes a second pointer value (which is represented by arrow 432)that refers back to resource block 421. Therefore, as long as a basestation successfully receives one of the GF transmissions of resourceblock 421 and resource block 422, based on the included points, the basestation can determine the other resource block on which the data payloadwas replicated.

FIG. 5 illustrates an embodiment 500 of a collision involving a two-wayfrequency-domain linked-list data structure. In embodiment 500, a GFtransmission was transmitted by a first UE on resource block 501 andresource block 502. On resource block 501, only the first UEtransmitted, thus there is no collision and the base station canproperly receive and decode the GF transmission of resource block 501.Included in the GF transmission of resource block 501 is pointer 511,which points to resource block 502.

At resource block 502, the first UE transmitted the same data payload atresource block 501. Additionally, a second UE transmitted a different GFtransmission at resource block 502, resulting in a collision as detectedby the base station, thus rendering both of the GF transmissions ofresource block 502 indecipherable by the base station (withoutadditional information). Since the base station received informationindicating that the same data payload of resource block 501 wastransmitted on resource block 502 due to pointer 511, the base stationmay perform successive interference cancellation (SIC) to resolve thecollision. The base station may effectively subtract the interferencecaused by the known content of the GF transmission of resource block 501from the received data collision. By subtracting this interference, thebase station may be able to successfully reconstruct the data payload ofthe second GF transmission from the second UE. The high level concept ofSIC is a subtraction of two received signals, however, in practice, somesignal processing techniques are needed before the subtraction. Forinstance, due to fading on different time slot or frequency dependentfading, some scaling may be needed before the subtraction process isperformed.

While FIGS. 4A-5 were focused on the frequency domain, the concept maybe applied and expanded to the time domain. FIG. 6A illustrates anembodiment of a one-way time-domain linked-list data structure. Inembodiment 600A, the sub-carrier frequencies in frequency domain and thetime slot varies for the multiple GF transmissions. Resource blocks tothe right represent resource blocks occurring during later time slots.Therefore, the GF transmission transmitted at resource block 601 istransmitted on four time slots earlier than the GF transmissiontransmitted at resource block 602. In a one-way time-domain linked-listdata structure, each GF transmission transmitted by a UE may include apointer to a past resource block that includes a same data payload. TheGF transmission of resource block 602 may include a pointer, representedby arrow 610, to the GF transmission of resource block 601. The GFtransmission of resource block 603 may include a pointer, represented byarrow 611, to the GF transmission of resource block 602. The GFtransmission of resource block 604 may include a pointer, represented byarrow 612, to the GF transmission of resource block 603. The GFtransmission of resource block 605 may include a pointer, represented byarrow 613, to the GF transmission of resource block 604. Additionally,the GF transmission of resource block 605 may include an additionalpointer indicating that no future GF transmission includes the samereplicated data payload. In other embodiments, rather than pointerspointing to a past resource block, pointers may point to a futureresource block, such as resource block 601 pointing to resource block602.

In embodiment 600A, each GF transmission is transmitted on a randomresource block that has a different timeslot and a different frequency.In other embodiments, multiple resource blocks having a same timeslotmay be used. Additionally or alternatively, multiple resource blockshaving a same sub-carrier frequencies in frequency domain may be used.

FIG. 6B illustrates an embodiment of a two-way time-domain linked-listdata structure. In embodiment 600B, the frequency band and the time slotvaries for the multiple GF transmissions. In a two-way time-domainlinked-list data structure, each GF transmission transmitted by a UE mayinclude two pointers: a first pointer to a past resource block thatincludes a same data payload and a second pointer to a future resourceblock that includes a same data payload. Since the UE may randomlyselect the resource blocks, resource blocks may be randomly selected inadvance of when the resource block occurs, thus allowing a GFtransmission to refer to a future resource block, such as a pointer(represented by arrow 628) in the GF transmission of resource block 602referring to resource block 603.

The GF transmission of resource block 631 may include a first pointer,represented by arrow 629, to the GF transmission of resource block 632.The GF transmission of resource block 631 may include a second pointer,represented by arrow 630, indicating that the data payload wastransmitted on no earlier resource blocks. The GF transmission ofresource block 632 may include a first pointer, represented by arrow628, to the GF transmission of resource block 633. The GF transmissionof resource block 632 may include a second pointer, represented by arrow621, indicating that the data payload was transmitted on resource block631. The GF transmission of resource block 633 may include a firstpointer, represented by arrow 627, to the GF transmission of resourceblock 634. The GF transmission of resource block 633 may include asecond pointer, represented by arrow 622, indicating that the datapayload was transmitted on resource block 632. The GF transmission ofresource block 634 may include a first pointer, represented by arrow626, to the GF transmission of resource block 635. The GF transmissionof resource block 634 may include a second pointer, represented by arrow623, indicating that the data payload was transmitted on resource block633. The GF transmission of resource block 635 may include a firstpointer, represented by arrow 625, indicating that no future resourceblock contains a replicated version of the data payload. The GFtransmission of resource block 635 may include a second pointer,represented by arrow 624, indicating that the data payload wastransmitted on resource block 634.

FIG. 6C illustrates an embodiment 600C of a time-domain linkedpseudorandom code linked data structure. In embodiment 600C, resourceblocks 631-635 each include the same payload of data. However, pointersare not present in the data transmitted on each of these resourceblocks. Rather, both the instance of UE and the base station have storeda pseudo-random code that periodically repeats. This pseudo-random codedefines a pattern of resource blocks that varies in the time-domain andfrequency-domain, such as illustrated in FIG. 6C. In other embodiments,the pattern may vary in only the frequency domain or only the timedomain.

The initial pseudo-random code may be created and stored by the basestation and transmitted to the instance of UE. The instance of UE maystore the pseudo-random code and use it to repeat a transmission of datafor GF transmissions. Alternatively, the initial pseudo-random code maybe created by the instance of UE and transmitted to the base station.The base station may store an indication of the pseudorandom code. Whena collision occurs, the base station may access the pseudorandom code todetermine other resource blocks on which the UE is expected to transmitthe same data as on the resource block on which the collision occurred.

The use of a pseudorandom code may have the advantage that data relatedto pointers does not need to be transmitted, thus decreases the amountof overhead that needs to be transmitted on resource blocks. When a UEmoves and begins communicating with a different base station, the basestation may provide a new pseudorandom code, the UE may provide amessage indicative of its current pseudorandom code, or the wirelessnetwork may provide the different base station with an indication of thepseudorandom code.

FIG. 7 illustrates an embodiment 700 of a consecutive index time-domaindata structure. For example in some embodiments, only the time slot maybe variable and the sub-carrier frequencies may be fixed. In suchembodiments, rather than using a pointer, the replicated GFtransmissions may be sent on temporally-consecutive resource blocks onthe same subcarrier frequency along with an index value. Each GFtransmission may be numbered and may include an indication of a totalnumber of transmissions, thus the base station may be able to determinethe number of replicated GF transmissions that were sent before andafter the successfully received GF transmission. In embodiment 700, asame payload is transmitted on resource blocks 701, 702, 703, 704. Eachof these transmissions may include a different index and may indicatethe total number of transmissions. For instance, the data transmitted atresource block 701 may indicate index 1 of 4; resource block 702 mayindicate index 2 of 4; resource block 703 may indicate index 3 of 4; andresource block 704 may indicate index 4 of 4. In some embodiments, thebase station may have a stored indication of the number replicated GFtransmissions that may be sent for various types of UE. Therefore, if asuccessfully-received GF transmission is labeled with a particularvalue, the base station may be able to determine the number ofreplicated GF transmissions occurring before and after the successfullyreceived GF transmission. For example, in embodiment 700, the predefinednumber of values is four. In still other embodiments, adjacentsub-carrier frequencies may be used instead of consecutive time slots(or mini-slots).

Various methods may be performed using the arrangements of FIGS. 1-7.FIG. 8 illustrates an embodiment of a method for using a linked-listdata structure to correct for grant-free transmission collisions. Method800 may be performed by system 100, which can include UE and a basestation.

At block 802, instances of UE in communication with a base station maybe provided UE configuration data that defines how the instances of userequipment can perform GF transmissions. The UE configuration data maydefine: which resource blocks are allocated for GF transmissions; thenumber of times a message should be sent as a GF transmission; whetherfrequency should be randomized; whether timeslot should be randomized;and whether unidirectional or bi-directional pointers are to be includedin the uplink GF transmissions. In some embodiments, the UEconfiguration data is received at an earlier time from another basestation or is stored onto the UE as part of an initial configuration(e.g., performed at manufacture).

At block 805, a first UE may determine it has data that is to betransmitted to a base station as a GF transmission. In response to thisdetermination, at block 810, the first UE may need to wait until a nextscheduled time period when grant-free resource blocks are present.Additionally, at block 805, the first UE may randomly select multipleresource blocks. The UE may have data locally stored that indicates thetime slots and sub-carrier frequencies of available GF resource blocks.Such data may have been previously provided to the UE by the basestation, by the cellular network, or stored as part of the UE'sconfiguration data. In some embodiments, the resource blocks vary onlyin frequency; in other embodiments, the resource blocks vary only intime; and in still other embodiments, the resource blocks vary in bothtime and frequency. The number of resource blocks selected may be atleast two. The base station may have previously provided the first UEwith a number of repetitions to perform. Alternatively, the first UE mayhave a stored default number of repetitions to transmit.

At block 815, the GF transmission may be transmitted multiple times ondifferent resource blocks. Each GF transmission may be a replica of theother GF transmissions sent at block 815. The only difference betweenthe GF transmissions may be the included pointers. Each GF transmissionmay include one, two, or more than two pointers. A pointer may point toa next GF transmission (e.g., higher set of sub-carrier frequencies,later in time, lower set of sub-carrier frequencies, and/or earlier intime). Two pointers may be present to point to the next and previous GFtransmissions. A pointer may also be self-referential to the GFtransmission in which it is included to indicate that the GFtransmission is a first or last GF transmission of a group of replicatedGF transmissions.

Of the multiple GF transmissions sent on the different set ofsub-carrier frequencies, different time slots, or both, at least one maybe received and decoded by the base station without a collisionoccurring with another GF transmission from another UE at block 820. Thedata payload received and successfully decoded at block 820 may berouted to an external network (e.g., the Internet), via some otherprivate or public network, or otherwise processed at block 825.

At block 830, the base station may determine whether a GF uplinktransmission collision occurred on another resource block that is linkedto the successfully decoded GF transmission via one or more pointersincluded in the one or more GF transmissions of block 820. A collisionmay be identified by the base station determining that multiple GFtransmissions have been received, but that the amount of interference istoo great to interpret the contents of the multiple received GFtransmissions without further information. If block 830 is determined inthe negative and there are no collisions, method 800 may end at block835.

At block 840, if block 830 is determined in the positive, method 800 mayproceed to block 840. At block 840, successive interference cancellation(SIC) may be performed to subtract the data payload of the successfullydecoded GF transmission of block 820 from the collision signal. Bysubtracting the successfully decoded GF transmission of block 820, thebase station may be able to reconstruct a GF transmission transmitted bya second UE that happened to transmit on the same resource block as areplicated GF transmission from the first UE. The data payload of the GFtransmission from the second UE that was successfully reconstructed atblock 840 may be routed to an external network (e.g., the Internet), viasome other private or public network, or otherwise processed at block845.

The methods, systems, and devices discussed above are examples. Variousconfigurations may omit, substitute, or add various procedures orcomponents as appropriate. For instance, in alternative configurations,the methods may be performed in an order different from that described,and/or various stages may be added, omitted, and/or combined. Also,features described with respect to certain configurations may becombined in various other configurations. Different aspects and elementsof the configurations may be combined in a similar manner. Also,technology evolves and, thus, many of the elements are examples and donot limit the scope of the disclosure or claims.

Specific details are given in the description to provide a thoroughunderstanding of example configurations (including implementations).However, configurations may be practiced without these specific details.For example, well-known circuits, processes, algorithms, structures, andtechniques have been shown without unnecessary detail in order to avoidobscuring the configurations. This description provides exampleconfigurations only, and does not limit the scope, applicability, orconfigurations of the claims. Rather, the preceding description of theconfigurations will provide those skilled in the art with an enablingdescription for implementing described techniques. Various changes maybe made in the function and arrangement of elements without departingfrom the spirit or scope of the disclosure.

Also, configurations may be described as a process which is depicted asa flow diagram or block diagram. Although each may describe theoperations as a sequential process, many of the operations can beperformed in parallel or concurrently. In addition, the order of theoperations may be rearranged. A process may have additional steps notincluded in the figure. Furthermore, examples of the methods may beimplemented by hardware, software, firmware, middleware, microcode,hardware description languages, or any combination thereof. Whenimplemented in software, firmware, middleware, or microcode, the programcode or code segments to perform the necessary tasks may be stored in anon-transitory computer-readable medium such as a storage medium.Processors may perform the described tasks.

Having described several example configurations, various modifications,alternative constructions, and equivalents may be used without departingfrom the spirit of the disclosure. For example, the above elements maybe components of a larger system, wherein other rules may takeprecedence over or otherwise modify the application of the invention.Also, a number of steps may be undertaken before, during, or after theabove elements are considered.

What is claimed is:
 1. A method for performing uplink grant-freetransmissions, the method comprising: determining, by a first userequipment (UE), data that is to be transmitted using a grant-free uplinktransmission to a base station of a cellular network; selecting, by thefirst UE, a first grant-free resource block, wherein: a plurality ofgrant-free resource blocks define a plurality of subcarrier frequencies,a plurality of timeslots, or both for data to be transmitted to the basestation of the cellular network without a reservation; selecting, by thefirst UE, a second grant-free resource block; and transmitting, by thefirst UE, a grant-free transmission that comprises a data payload, afirst pointer, and a second pointer at the first grant-free resourceblock, wherein: the first pointer refers to the second grant-freeresource block; and the second pointer refers to the first grant-freeresource block and is indicative of the data payload not beingtransmitted on any later grant-free resource block.
 2. The method forgrant-free transmissions of claim 1, wherein the first grant-freeresource block and the second grant-free resource block occur duringdifferent timeslots on a same set of frequencies.
 3. The method forgrant-free transmissions of claim 1, wherein the first grant-freeresource block and the second grant-free resource block occur duringdifferent timeslots on different frequencies.
 4. The method forgrant-free transmissions of claim 1, further comprising: transmitting,by the first UE, a second grant-free transmission that comprises thedata payload and a third pointer at the second grant-free resourceblock.
 5. The method for grant-free transmissions of claim 4, furthercomprising: receiving, by the base station, the grant-free transmissiontransmitted by the first UE on the first grant-free resource block;detecting, by the base station, a collision on the second grant-freeresource block, wherein the collision results from the second grant-freetransmission being received during a same timeslot and a same frequencyas a third grant-free transmission from a second UE distinct from thefirst UE; and based on the first pointer of the grant-free transmission,performing interference cancelation to subtract at least a portion ofthe grant-free transmission from the received collision to reconstructthe third grant-free transmission transmitted by the second UE at thesecond grant-free resource block.
 6. The method for performing thegrant-free transmission of claim 1, wherein the base station is part ofa 5G cellular network.
 7. The method for performing the grant-freetransmission of claim 1, wherein selecting the first grant-free resourceblock and selecting the second grant-free resource block is performedrandomly by the first UE.
 8. A system that performs uplink grant-freetransmissions, the system comprising: a cellular network comprises aplurality of base stations, the plurality of base stations comprising abase station; a plurality of user equipment (UE), wherein a first UE ofthe plurality of UE is configured to: determine data that is to betransmitted using a grant-free uplink transmission to the base stationof the cellular network; select a first grant-free resource block,wherein: a plurality of grant-free resource blocks define a plurality ofsubcarrier frequencies, a plurality of timeslots, or both for data to betransmitted to the base station of the cellular network without areservation; select a second grant-free resource block; and transmit agrant-free transmission that comprises a data payload, a first pointer,and a second pointer at the first grant-free resource block, wherein:the first pointer refers to the second grant-free resource block; andthe second pointer refers to the first grant-free resource block and isindicative of the data payload not being transmitted on any latergrant-free resource block.
 9. The system that performs uplink grant-freetransmissions of claim 8, wherein the first grant-free resource blockand the second grant-free resource block occur during differenttimeslots on different frequencies.
 10. The system that performs uplinkgrant-free transmissions of claim 8, wherein the first UE of theplurality of UE is configured to: transmit a second grant-freetransmission that comprises the data payload and a third pointer at thesecond grant-free resource block.
 11. The system that performs uplinkgrant-free transmissions of claim 10, wherein the base station isconfigured to: receive the grant-free transmission transmitted by thefirst UE on the first grant-free resource block; detect a collision onthe second grant-free resource block, wherein the collision results fromthe second grant-free transmission being received during a same timeslotand a same frequency as a third grant-free transmission from a second UEdistinct from the first UE; and based on the first pointer of thegrant-free transmission, perform interference cancelation to subtract atleast a portion of the grant-free transmission from the receivedcollision to reconstruct the third grant-free transmission transmittedby the second UE at the second grant-free resource block.
 12. The systemthat performs uplink grant-free transmissions of claim 8, wherein thecellular network is a 5G NR cellular network.
 13. The system thatperforms uplink grant-free transmissions of claim 8, wherein selectingthe first grant-free resource block and selecting the second grant-freeresource block is performed randomly by the first UE.
 14. A system thatperforms uplink grant-free transmissions, the system comprising: acellular network comprises a plurality of base stations, the pluralityof base stations comprising a base station; a plurality of userequipment (UE), wherein each UE of the plurality of UE is configured to:determine data that is to be transmitted using a grant-free uplinktransmission to the base station of the cellular network; select a firstgrant-free resource block, wherein: a plurality of grant-free resourceblocks define a plurality of subcarrier frequencies, a plurality oftimeslots, or both for data to be transmitted to the base station of thecellular network without a reservation; select a second grant-freeresource block; and transmit a grant-free transmission that comprises adata payload, a first pointer, and a second pointer at the firstgrant-free resource block, wherein: the first pointer refers to thesecond grant-free resource block; and the second pointer refers to thefirst grant-free resource block and is indicative of the data payloadnot being transmitted on any lower frequency grant-free resource block.15. A system that performs uplink grant-free transmissions, the systemcomprising: a cellular network comprises a plurality of base stations,the plurality of base stations comprising a base station; a plurality ofuser equipment (UE), wherein each UE of the plurality of UE isconfigured to: determine data that is to be transmitted using agrant-free uplink transmission to the base station of the cellularnetwork; select a first grant-free resource block, wherein: a pluralityof grant-free resource blocks define a plurality of subcarrierfrequencies, a plurality of timeslots, or both for data to betransmitted to the base station of the cellular network without areservation; select a second grant-free resource block; and transmit agrant-free transmission that comprises a data payload, a first pointer,and a second pointer at the first grant-free resource block, wherein:the first pointer refers to the second grant-free resource block; andthe second pointer refers to the first grant-free resource block and isindicative of the data payload not being transmitted on any higherfrequency grant-free resource block.